Styrene resins of controlled properties

ABSTRACT

LUSTROUS PERARLIZED SHEETS FOR USE IN BUTTON BLANK MANUFACTURE ARE MADE FROM A STYRENE-DIVINYLBENZENE COPOLYMER FORME BY A PREPOLYMER SYRUP HAVING A LATENT GEL STRUCTURE. PEARLIZED PIGMENT PARTICLES ARE ADDED TO THE PRE-POLYMER SYRUP AND SUBJETED TO MOVEMENT IN ORDER TO EFFECT SYSTEMATIC ORIENTATION OF THE PARTICLES.

United States Patent Int. Cl. C08f 45/04 US. Cl. 260-41 2 ClaimsABSTRACT OF THE DISCLOSURE Lustrous pearlized sheets for use in buttonblank manufacture are made from a styrene-divinylbenzene copolymerformed by a prepolymer syrup having a latent gel structure. Pearlizedpigment particles are added to the pre-polymer syrup and subjected tomovement in order to effect systematic orientation of the particles.

CROSS-REFERENCE TO RELATED APPLICATIONS This application is a divisionof our copending application Ser. No. 584,382, filed Oct. 5, 1966, nowU.S. Pat. No. 3,493,636.

This invention relates to a new method of making styrene-divinylbenzenecopolymers. In one specific aspect, it relates to styrene-divinylbenzenecopolymers of improved properties made by the controlled introduction ofdivinylbenzene during the polymerization of the resinous mass.

It is well known that the heat resistance, solvent resistance, andimpact strength of styrene polymers can be modified by the incorporationof a minor amount of divinylbenzene, which serves to cross-link the longpolystyrene chains, thereby forming a three-dimensional polymericnetwork. Conventionally, such polymers are made by mixing the twomonomers and polymerizing at an elevated temperature in the presence ofa suitable amount of a free radical initiator. Special polymers ofstyrene and divinylbenzene have been reported by G. F. DAlelio in US.Pat. 2,405,817. According to DAlelio, a soluble, fusible polymer ofdivinyl benzene is first isolated from its solution in diethylbenzeneand thereafter mixed with styrene and copolymerized.

The physical properties of the known styrene-divinylbenzene copolymersvary considerably, but, in general, these copolymers are characterizedby improved resistance to solvents, heat, and impact. The degree ofimprovement in properties is known to be measurably influenced by theamount of divinylbenzene present in the copolymer. The influence ofdivinylbenzene content in typical styrenedivinylbenzene copolymers isreported in Boundy and Boyer, Styrene, Its Polymers, Copolymers andDerivatives, Reinhold Publishing Corporation (1952), on page 725.According to Boundy and Boyer, the impact strength ofstyrene-divinylbenzene copolymers increases with the first small amount(about five percent) of divinylbenzene and then falls off rapidlybecause of the embrittling effect of divinylbenzene in the copolymer.

We have discovered a novel method of making styrenedivinylbenzenecopolymers involving the controlled distribution of divinylbenzenewithin the polymer network. The controlled distribution ofdivinylbenzene permits variation in polymer properties as desired forparticular end use applications. It also makes it possible to introducemore divinylbenzene into the copolymer without causing embrittlementand, with the selection of special conditions, provides products ofgreater impact strength than those reported by Boundy and Boyer.

It is known that, during the polymerization of conventionalstyrene-divinylbenzene copolymers, an abrupt structural transitionoccurs and the viscosity of the liquid monomer-polymer mixture increasessuddenly until is no longer flows. At this point (at about five to tenpercent polymerization), a gel has formed as a result of the linkingtogether of polymer molecules in a three-dimensional lattice *work ofindefinitely large size. As the polymerization continues, the complexityof the lattice structure increases and the gel becomes mechanicallystronger, thus resulting in a rigid polymer. Because of the tendency ofthe gel to form at very early stages of the polymerization, it has beendifficult to use styrene-divinylbenzene copolymers eifectively .inreinforced plastics and in other applications involving impregnation orthe introduction of special filler materials prior to completepolymerization. The mixed monomer system has insuificient viscosity forthese applications and a partial polymerization results in too drastican increase in viscosity because of gel formation. DAlelio sought toovercome these problems by dissolving a fusible polymer ofdivinylbenzene in styrene, but the DAlelio product is largely apolymerized mixture of divinylbenzene and styrene polymers, rather thanan integrated copolymer.

The manufacture of sheeting for button blanks requires a polymericproduct having good hot abrasion resistance, good solvent resistance,and good impact strength. Ordinarily, button blanks are made frompolyesters or polymethacrylates. Modified styrene resins, such as thestyrenedivinylbenzene copolymers, have not been heretofore useful inbutton blank manufacture, because the conventionalstyrene-divinylbenzene polymers were found to be substandard in theirproperties or unsuitable from the standpoint of required processingsteps.

The manufacture of button blanks involves the incorporation andcon-trolled orientation within the polymeric mass of a pearlescentpigment, commonly flat platelets or crystals of basic lead carbonate, inthe millimicron size range. The luster or sheen of button blanks isprovided by the introduction of the pearl pigment in an ordered andsystematic orientation. Pearl pigment cannot be oriented in a mixture ofstyrene-divinylbenzene monomers. If the mixed monomers are partiallypolymerized, it is possible to orient the pigment, but because of theabrupt gelation of a copolymer having the required divinylbenzenecontent, the system is impractical and cannot be safely handled incommercial equipment. Moreover, the internal strain present within thecopolymer is sufiicient to cause cracking of the cast sheet duringmolding. If the amount of divinylbenzene used is reduced to decrease therate of gel formation, the physical properties required for the finalproduct are no longer achieved.

We have discovered that a styrene-divinylbenzene copolymer of controlledproperties can be made by first preparing a pre-polymer syrup,characterized by a latent gel stnlcture and containing a critical amountof divinylbenzene. The novel syrup is stable and is characterized by asolution viscosity in a range useful for the impregnation of paper,textile fibers, and glass roving or mats. The intrinsic viscosity of thenovel syrup is sufiiciently high to orient pearl pigment, and polymersof unexpectedly high impact strength are obtained by introducingadditional divinylbenzene during subsequent polymerization. Thesubsequent introduction of divinylbenzene provides a controlleddistribution of divinylbenzene throughout the polymeric network.

It is therefore an object of the invention to provide a novel method ofmaking styrene-divinylbenzene copolymers of controlled properties whichcan be effectively used in applications for which conventionalstyrenedivinylbenzene resins have been considered unsuitable.

In accordance with the invention, a styrene-divinylbenzene copolymercontaining up to 12 percent by weight divinylbenzene is made by firstforming a pre-polymer syrup having a latent gel structure. The syrup isobtained by polymerizing styrene and from 1-3.5 percent by weight, basedon the total weight of monomer charge, of divinylbenzene by heating astirred mixture of styrene and divinylbenzene to an elevated temperaturein the presence of sufiicient free radical initiator to provide apolymerization rate of 5 to 80 percent per hour. The polymerization iscontinued under agitation for a period of time until the intrinsicviscosity of the mixture is at least 0.65 dl./g. in toluene at 30 C. andis terminated before gelation occurs by cooling the reaction mixture.The resulting polymer syrup can be stabilized if desired by the additionof a small amount of polymerization inhibitor.

The syrup contains generally between ten and forty percent by weightstyrene-divinylbenzene copolymer in admixture with unreacted monomers.The stable syrup can be used as an impregnant and polymerized in situ toform first a rubbery B-stagc copolymer which is then cured to across-linked infusible mass. The impact strength and other properties ofthe copolymer are materially improved by adding to the syrup additionaldivinylbenzene to bring the total divinylbenzene content of the finalcopolymer to 4-12 percent by weight. The additional divinylbenzene canbe added before, during, or after the cooling step.

In a special embodiment of the invention, pearl pigment, additional freeradical initiator, and additional divinylbenzene to bring the totalcontent of divinylbenzene to 4-12 percent by weight are added to thesyrup. The pearl pigment is subjected to movement within the syrup,conveniently by placing the syrup in a moveable or vibrating mold, whichcauses ordered orientation of the pigment. Polymerization is continuedby heat curing at a temperature of 60-90 C. until reaction is complete.The resulting product is a tough, solvent-resistant, heatresistant,lustrous sheet of good impact strength. Button blanks are made from thesheet by reheating the sheet in an oven at approximately 150 C. for ashort period of time and cutting the hot sheet into blanks of thedesired size.

Divinylbenzene can be used in the invention either as substantially puremonomer or as the usual commercial mixture of divinylbenzene isomers,ethylvinylbenzene, and minor amounts of other impurities. It is lessexpensive and, therefore, advantageous to use the commercially availablemixtures, which range in divinylbenzene content from 50-60 percent byweight. Commercial mixtures generally contain divinylbenzene in a 2:1ratio of meta: para isomers. Such mixtures also ordinarily contain apolymerization inhibitor which should be removed before use.

In the preparation of the novel pro-polymer syrup, the amount ofdivinylbenzene present is critical. If less than about one percent byweight divinylbenzene is used, the final product is not resistant tosolvent attack. If greater than about 3.5 percent by weight is present,the pre-polymerization is extremely difficult to control because ofrapid gel formation. Furthermore, the rapid formation of the gel sets upgreat internal strains within the polymeric network and the resultingmaterial tends to crack during casting.

To make the syrup, styrene monomer and, if desired, the required amountof divinylbenzene are charged to a suitable reactor, which isconveniently equipped with a heating unit and cooling facilities, suchas a water jacket or internal cooling coils. Alternatively, the styreneonly is charged to the reactor and the divinylbenzene is added to thepolymerization mixture as the reaction progresses. A suitable agitatoris provided for continuous Stirring of the reaction mass.

Polymerization is accomplished at an average rate of five to eightypercent per hour, preferably twenty to sixty percent per hour, by anappropriate selection of temperature conditions and amount and type offree radical initiator. The rate of polymerization also varies with theamount of divinylbenzene present in the system. Polymerization ofsystems containing the maximum divinylbenzene content (about 3.5 percentby weight) can "be controlled within the desired rate range by usingless catalyst and lower polymerization temperatures.

The rate of the pre-polymerization has an important bearing on theproperties of the final product. If polymerization is too rapid, thereaction is difiicult to control and the latent gel structure within thepre-polymer will contain a large amount of internal strain, which tendsto cause cracking in the finished casting. Very slow polymerizationrates are not commercially practical.

Convenient operating temperatures for producing the desiredpolymerization rate range between 50 and C. It is possible to usetemperatures higher than 100 C., although this requires the use ofpressurized equipment. At temperatures below 50 C., the reactionproceeds at a rate which is not generally commercially useful.

Suitable free radical initiators include those capable of releasing freeradicals at the pre-selected polymerization temperatures, e.g., 50-l00C. Useful initiators thus include peroxide-type initiators, such asbenzoyl peroxide, lauroyl peroxide, acetyl peroxide, caprylyl peroxide,decanoyl peroxide, propionyl peroxide, t-butylperoxypivalate,t-butylperoxyisobutyrate, 2,4-dichlorobenzoyl peroxide, pchlorobenzoylperoxide, succinic acid peroxide, isopropyl percarbonate, and the like.Particularly useful are the azo initiators, such asazo-bis-isobutyronitrile.

The amount of free radical initiator used ordinarily varies betweenabout 0.05 and 0.50 percent by weight, based upon the total weight ofthe polymerization mass. If the amount of free radical initiator isincreased, the rate of reaction is increased but the molecular weight(indicated by the intrinsic viscosity) is reduced. For polymers in thelower range of useful divinylbenzene content, it is advantageous, fromthe standpoint of impact strength, to use less initiator and to allowthe chains of pre-polymer to grow to greater length. The use of lessinitiator also makes the reaction more easily controllable, because therate of reaction obviously decreases with decreasing initiator contentand there is less initiator present when termination of thepolymerization is required. The rate of reaction can also be controlledby adding the initiator incrementally as the reaction progresses. Thelength of the polymer chains can be regulated by the addition of chaintransfer agents, such as lauryl mercaptan, t-dodecylmercaptan,n-dodecylmercaptan, and the like, in amounts of about 0.05-0.5 percentby weight of the total polymerization mass.

As the polymerization of the syrup progresses, the intrinsic viscosity,measured in toluene at 30 C., increases at first gradually and thenabruptly. The abrupt change in intrinsic viscosity, which occurs at aviscosity of about 0.4-0.6 dl./g., depending upon the divinylbenzenecontent of the system, is indicative of the formation of the latent gelstructure. In the preparation of the pre-polymer, polymerization isallowed to continue beyond this point, that is, to above about 0.65 dl./g. At an intrinsic viscosity of about 0.65 dl./g., the pre-polymer iscapable of orienting pearl pigment and is generally useful inapplications requiring an impregnation step. As the polymerizationprogresses further, the mass reaches the point of incipient visible gelformation. Pro-polymerization must be terminated at this point and anyvisible gel formed in the reaction mixture can be eliminated byincreasing the speed of agitation. Rapid agitation causesdisentanglement of polymer chains and results in the elimination ofvisible gel from the system.

Polymerization is terminated by cooling with water, using eitherinternal cooling coils or a jacketed kettle. If

a very rapid cooling is desired, special low temperature coolants can,of course, be used.

The pre-polymer syrup thus made can, if desired, be stabilized by apolymerization inhibitor, such as hydroquinone or p-t-butylcatechol. Thesyrup has an intrinsic viscosity ranging between about 0.65 and 1.5dl./g. and a syrup viscosity between about 100 and 12,000 cps.

For those applications in which superior physical properties arerequired, the amount of divinylbenzene present in the ultimate copolymermust be increased over the amount contained in the pre-polymer syrup. Apolymer having a spaced distribution of divinylbenzene is made by addingto the syrup, either before, during, or after cooling, an additionalamount of divinylbenzene to bring the total weight of divinylbenzenefrom 4-12 percent by weight. Additional free radical initiator should beadded at this point to assist in the completion of the polymerization.The preferred initiator and the amount added depends upon the conditionsof cure. The amount of added initiator generally ranges between about0.1 and 0.5 percent by weight, based upon the total weight of thepolymerization mass.

In the preparation of clear cast sheets or reinforced plastics, thecuring is generally carried out at a temperature between about 60 and150 C., using pressures varying from the pressure of simple contact upto about 500 lbs/sq. in. In preparing the lustrous sheets for use inbutton blank manufacture, curing is done at a lower temperature to avoidthe adverse effect of excessive heat on the pearl pigment. Suitablecuring temperatures for button blank sheets range between about 60 and90 C., and curing generally is accomplished in a period of from 25hours.

The button blank sheets are prepared by adding to the pre-polymer syrupadditional divinylbenzene to provide a total divinylbenzene content of412 percent by weight, additional free radical initiator to promotecuring, and from 0.25-2 percent by weight pearl pigment. The pearlpigment can be natural pearlescence, obtained from fish scales, or anyof the available types of synthetic pearlescence, preferably basic leadcarbonate. Synthetic pearlescence is commercially available in the formof 11-60 percent dispersions in an organic solvent. Orientation of thepearl pigment is accomplished by any of the recognized methods in theart for causing the pigment to move within a viscous syrup, convenientlyby subjecting the mold to movement, vibration, or reciprocating motion,as described in US. Pat. 2,971,223 by Louis Grunin et al. It is alsopossible to orient the crystals by centrifugal casting, as shown byGerson in US Pat. 2,856,635, or electrical excitation, as described inHunsdiecker patent, US. 3,073,732. The polymeric mass is then cured asdescribed hereabove, resulting in a cast sheet of excellent pearlyluster.

Our invention is further illustrated by the following examples.

Example I To a stainless steel, full jacketed kettle, 24 in. in diameterand 26 in. deep with an open top and equipped with a large and smallagitator, there was charged 243 lbs. styrene monomer. The styrene washeated to atemperature of 81 C. and, with stirring using the smallagitator, 114 g. (0.1 percent by weight, based on the weight of charge)of azo-bis-isobutyronitrile was added thereto. At a rate of 75 ml. perminute, 8 lbs. 2 oz. of commercial (57 percent) divinylbenzene(corresponding to about 1.7 percent divinylbenzene, based on the weightof charge) was added to the stirred reaction mixture. The temperaturereached 8893 C. and was maintained at this level. After about 5660minutes, the mass became stringy and viscous. The small agitator wasturned otf and the larger agitator was set at low speed. The agitationwas sufficient to disentagle the visible gel and the mass once morebecame clear and smooth. The average polymerization rate was 26.2percent per hour. At the completion of the reaction, 18 lbs. 4 oz. ofcommercial divinylbenzene (corresponding to about 4 percentdivinylbenzene, based on the weight of the charge) was added and the mixwas cooled to room temperature. The syrup containing the additionaldivinylbenzene was stabilized with 0.005 percent t-butylcatechol. Thesyrup had an intrinsic viscosity of 1.17 dl./g. measured in toluene at30 'C., a syrup viscosity (Brookfield) of 760 cps. (spindle LV-3 at 60rpm), and contained 21.4 percent by weight copolymer in admixture withunreacted monomer. A portion of the syrup was used to make clearcastings by adding 0.3 percent by weight lauroyl peroxide and curing at71 C. for four hours. To another portion of the syrup there was added1.3 percent by weight of a 35 percent by weight dispersion of basic leadcarbonate synthetic pearlescence. After adding 0.3 percent by weightlauroyl peroxide, the syrup containing the pearl pigment was placed in avibrating mold and cured for four hours at 71 C. There was thus obtaineda uniform lustrous sheet suitable for fabrication of button blanks.

The impact strength of the clear and pearled cast sheets was evaluatedusing a modification of the standard Gardner Impact Strength Test. Inthe modification a lighter weight (45 g.) was used in order to permitmeasurements to be made in smaller units than one in.-lb. The F valuesthus obtained were corrected for the change in falling weight. The clearcasting had an impact strength of 1.84 in.-lbs. and the pearl castingone of 0.93 in.-lb. An impact strength of 1.84 in.-lbs. corresponds tothe maximum reported by Boundy and Boyer for styrenedivinylbenzenecopolymers The clear casting was evaluated for solvent resistance bysubjecting a weighed sample to Soxhlet extraction with toluene for 56hours. The contents of the receiver were evaporated to constant weight.The toluene extractables of cast sheets amounted to about 2.3 percent,showing excellent solvent resistance.

The clear and pearled sheets were heated in an oven at C. for about sixminutes and cut hot into button blanks. The blanks were evaluated forresistance to hot iron abrasion and detergents.

The hot iron test was made by placing six buttons on a cloth-wrappedboard face up and placing a small hotplate (weight about three lbs.)upside down so that the hotplate surface made direct contact with theface of the buttons. The buttons were thus subjected to a temperature of550 F. for periods of one to three minutes. Both the clear and thepearled button blanks showed excellent resistance after a one minuteexposure and good resistance after three minutes exposure.

The detergent test was made for 16 and 24 hour periods by placing thebuttons in a jar containing 0.5 percent by weight Oxydol detergentsolution in tap water and placing the jar in an oven maintained at 93 C.After 16 hours of exposure, both the clear and pearled samples underwentsome degradation, but were'still within the range of acceptability. Thepearled sheet showed no additional degradation after 24 hours, but theclear casting degraded to a measurable extent. Polyester button blanksdegrade. measurably after three hours When subjected to this test.

Example II The procedure of Example I was substantially repeated withthe exception that the amount of divinylbenzene added after thepreparation of the syrup was varied. In one run 4.65 lbs. of commercialdivinylbenzene (2.3 percent by weight of the charge) was added aftercompletion of the syrup preparation, and in the second run 11.65 lbs. ofadditional divinyl-benzene (5.7 percent by weight of the charge) wasadded. The first syrup (containing less added divinylbenzene) contained18.5 percent copolymer and had an intrinsic viscosity of approximately1.1 dl./g. The second syrup contained 14.8 percent copolymer and had anintrinsic viscosity of 1.14 dl./g.

Clear and pearled castings were made from the two syrups as described inExample I. The impact strength of the clear castings from the firstsyrup were 1.36 in.-lbs. and the toluene extractables were 1.9 percent.Castings from the second syrup had impact strengths of 1.52 (clear) and0.83 (pearled) in.-lbs. The toluene extractables were 1.5 percent byweight. The clear and pearled castings from both syrups showed goodresistance to hot iron abrasion. The detergent resistance of clearcastings made from the first syrup was poor, but the detergentresistance of clear castings made from the second syrup was excellent.The results indicate that a better quality product, particularly fromthe standpoint of detergent resistance, can be made by introducing moredivinylbenzene into the system after the preparation of the pre-polymer.

Example III A series of experiments were made in laboratory equipment bycharging 365.3 g. of styrene to a one-quart friction top reactorequipped with an air stirrer. The air stirrer speed was adjusted to750-800 r.p.m. to simulate plant conditions. The reactor was surroundedby a water bath which was brought to the desired temperature. A seriesof runs Were made at 90 C. using varying amounts ofazo-bis-isobutyronitrile initiator. A 10.4 g. quantity of commercial(57.6 percent) divinylbenzene (1.5 percent divinylbenzene, based on thecharge) was charged at a linear rate throughout the entirepolymerization period. Samples were withdrawn at intervals to provideinformation on conversion and molecular weight (intrinsic viscosity).When the reaction mass reached the desired viscosity, cooling water wasturned on and the remainder of the divinylbenzene (24.3 g. of commercialmaterials, 3.5 percent by weight of the charge) was added at once. Afinal sample was taken for conversion and molecular weight after thebath had been cooled below 40 C. The syrups thus prepared werestabilized for further use by adding a small amount ofp-t-butylcatechol. The results for runs made at concentrations of 0.1,0.2, and 0.3 percent by weight of total charge ofazo-bis-isobutyronitrile are shown below in Table I. The polymerizationrates were 24, 37, and 45 percent per hour, respectively.

TAB LE I Conversions at at initiator initiator concentraconcentrations,I tions, percent dlJg. Time of sampling, min. 0. 1 0. 2 0. 3 0. 1 0. 20. 3

1 Measured in toluene at 0.

Example IV The procedure of Example III was substantially repeated using0.2 percent by weight of total charge of a20- bis-isobutyronitrile. Allof the divinylbenzene used in making the syrup (1.5 percent by weight ofcharge) was added at the start of the run. The final syrup contained22.4 percent by weight polymer and had an intrinsic viscosity of 1.06dl./g.

Example V The procedure of Example III was substantially repeated using0.2 percent by Weight azo-bis-isobutyronitrile. A special divinylbenzene(90 percent by weight di-' vinylbenzene) was substituted for thecommercial divinylbenzene of Example III. The final syrup contained 32.5percent by weight polymer and had an intrinsic viscosity of 0.77 dL/g.

Example VI The procedure of Example III was substantially repeated usinga temperature of 75 C. and benzoyl peroxide and lauroyl peroxide asinitiators in place of azo-bisisobutyronitrile. The amounts of theperoxides used cor- 8 respond to 0.2 percent by weightazo-bis-isobutyronitrile on a molar basis. The polymerization rates were5 and 8 percent per hour, respectively. The results are shown in TableII.

TABLE II Conversion Sample time taken, min. percent 1] (IL/g.

Benzo l eroxide 0.294

60 p 3. 9 0. 40 9. 1 0. 48 14. 0 0. 47 16. 2 O. 51 17. 0 0. 52 17. 6 0.53 18. 9 0. 58 up1 22. 3 0. 93 Laure l eros' e 0 492 301-? 3. 7 0.38 456. 1 0. 37 60 8. 3 0. 39 75 10. 4 0. 41 12. 3 0. 46 101 13. 6 9. 49Final syrup l6. 0 0. 66

1 All samples contalned gel; measrred in toluene at 30 C. b 2 Equivalentto 0.2% by weight az0-bis-is0butyronitrile on a molar The results showthat using the peroxide initiators at 75 C., the desired intrinsicviscosity can be reached.

Example VII The procedure of Example III was substantially repeatedusing 0.1 percent azo-bis-isobutyronitrile as the initiator. Two runswere made; one using 0.1 percent by weight t-dodecylrnercaptan and theother using 0.1 percent by weight n-dodecylmercaptan as chain transferagents. The chain transfer agents were added to the styrene at thebeginning of the syrup preparation. The initial and final amounts ofdivinylbenzene were the same as those used in Example III. The syrupmade with t-dodecylmercaptan contained 20.2 percent polymer and had anintrinsic viscosity of 1.13 dl./g. That made with n-dodecylmercaptancontained 17 percent polymer and had an intrinsic viscosity of 1.26 dl./g.

Clear and pearled castings were made from both syrups as described inExample I. The impact strengths were 1.62 and 1.70 in.-lbs. (clearsheet) and 1.47 and 1.38 in.-lbs. (pearled), respectively. The pearledsheet showed a definite improvement in impact strength when compared tothose of Examples I and II All sheets had an excellent rating whensubjected to the hot iron test, and the detergent resistance of clearsheets made from both syrups was dramatically improved. The detergentresistance of the pearled sheets was acceptable in both cases.

Example VIII A 360 g. quantity of styrene and 40 g. of commercial (57percent) divinylbenzene (5.7 percent divinylbenzene, based on thecharge) were mixed together with 0.3 percent lauroyl peroxide and castinto a sheet by heating at 71 C. for four hours. The impact strength ofthe sheet was 1.19 in.-lbs. and the toluene extractables were about fourpercent. The results show that a cast sheet made from an identicalpolymer composition, but without the syruping step of the invention, isinferior in impact strength to clear castings made according to themethod of the invention. Furthermore, the simple mixture of monomers isincapable of orienting pearl and is unsuited for numerous otherapplications for which the novel stable syrup of the invention can beused.

Example IX The procedure of Example III was repeated using 0.15 percentby weight azobis-isobutyronitrile as the initiator. The amount ofdivinylbenzene added to the syrup was increased to 17.35 g. (2.5 percentbased on the charge) and the amount of additional divinylbenzene addedafter the formation of the syrup was reduced to 17.35 g. (2.5 percentbased on the charge). In a second experiment, 17.35 g. of divinylbenzene(2.5 percent) was added initially and 34.7 g. percent) was added afterthe formation of the syrup. Polymerization proceeded at a rate of 35.5percent per hour. The first syrup contained 22.3 percent polymer and hadan intrinsic viscosity of 0.99 dl./ g. The second syrup had a polymercontent of 21 percent and an intrinsic viscosity of 0.77 dL/g. Clearsheets cast from the first syrup had an impact strength of 2.49 in.-lbs.Pearled sheet made from the second syrup had an outstanding impactstrength of 2.10 in-lbs. Toluene extractables from clear sheets wereapproximately 2-3 percent.

Example X The procedure of Example III was repeated with the exceptionthat the ratio of initial divinylbenzene (added to the syrup) to finaldivinylbenzene was changed to correspond to approximately 1:9 commercialdivinylbenzene (0.5:4.5 percent based on the charge). A 0.2 percentquantity of azo-bis-isobutyrontrile was used as the initiator in thesyruping step. The resulting syrup contained 44.3 percent polymer andhad an intrinsic viscosity of 0.65 dl./ g. Clear castings made from thesyrup had an impact strength of only 0.54 in.-lb. and the tolueneextractables were in excess of 18 percent. The results show that ifinsufficient divinylbenzene is present in the syruping step, theoutstanding impact strength and solvent resistance of polymers madeaccording to the method of the invention cannot be obtained.

Example XI A 360 g. quantity of styrene was polymerized with 0.09percent by weight benzoyl peroxide at 78 C. for six hours. The resultingsyrup had a polymer content of 22.2 percent and a Brookfield viscosityof 700 cps. A 40 g. quantity of divinylbenzene (5.7 percent of thecharge) was added. The final polymer content, after the addition of thedivinylbenzene, was 20 percent and the intrinsic viscosity was 0.93dl./g. The syrup thus prepared was capable of orienting pearl in clearand cast sheets made therefrom as described in Example I. The impactstrength of the clear sheet was 0.94 in.-lbs., and the tolueneextractables were about 20 percent, indicating complete lack of solventresistance.

Example XII Syrup was made as described in Example IV from a mixture ofmonomers corresponding to 90 percent by Weight styrene and percent byweight commercial divinylbenzene. In one run no additionaldivinylbenzene was added, and in a second run an additional 5 percent byweight commercial divinylbenzene was added to the syrup upon cooling.The preparations were run at 80 C.

using 0.1 percent azo-bis-isobutyronitrile as the initiator. 5 Thesyrups thus prepared had an intrinsic viscosity in excess of 1.75 and apolymer content of about 6 percent. Castings made from both syrupscracked in the mold, presumably due to high internal strains.

We claim:

1. Method of making a styrene-divinylbenzene copolymer containing up to12 percent by weight divinylbenzene comprising:

(a) polymerizing styrene and from 1-3.5 percent by weight, based on thetotal Weight of monomer, of divinylbenzene by heating a stirred mixtureof styrene and divinylbenzene to a temperature of 50 to 100 C. in thepresence of sufiicient free radical initiator to provide apolymerization rate of 20 to 60 percent per hour;

(b) continuing the polymerization under agitation for a period of timeuntil the intrinsic viscosity of the mixture is at least 0.65;

(c) terminating the polymerization before gelation occurs to provide apre-polymer syrup, characterized by a latent gel structure, of copolymerin admixture with unreacted monomer;

(d) adding additional divinylbenzene to bring the total weight ofdivinylbenzene to 4 to 12 percent by weight;

(e) adding 0.25-2 percent by Weight pearl pigment;

(f) subjecting the pearl pigment particles in the prepolymer syrup tomovement to effect systematic orientation of said particles; and

(g) continuing the polymerization at a temperature of 60 to 90 C. in thepresence of additional free radical initiator until polymerization iscomplete.

2. Method according to claim 1 wherein the free radical initiator usedto provide the pre-polymer syrup is azobis-isobutyronitrile and theadded free radical initiator 40 is lauroyl peroxide.

MORRIS LIEBMAN, Primary Examiner J. H. DERRINGTON, Assistant Examiner

